"""Sparse accessor""" from __future__ import annotations from typing import TYPE_CHECKING import numpy as np from pandas.compat._optional import import_optional_dependency from pandas.core.dtypes.cast import find_common_type from pandas.core.dtypes.dtypes import SparseDtype from pandas.core.accessor import ( PandasDelegate, delegate_names, ) from pandas.core.arrays.sparse.array import SparseArray if TYPE_CHECKING: from scipy.sparse import ( coo_matrix, spmatrix, ) from pandas import ( DataFrame, Series, ) class BaseAccessor: _validation_msg = "Can only use the '.sparse' accessor with Sparse data." def __init__(self, data=None) -> None: self._parent = data self._validate(data) def _validate(self, data) -> None: raise NotImplementedError @delegate_names( SparseArray, ["npoints", "density", "fill_value", "sp_values"], typ="property" ) class SparseAccessor(BaseAccessor, PandasDelegate): """ Accessor for SparseSparse from other sparse matrix data types. Parameters ---------- data : Series or DataFrame The Series or DataFrame to which the SparseAccessor is attached. See Also -------- Series.sparse.to_coo : Create a scipy.sparse.coo_matrix from a Series with MultiIndex. Series.sparse.from_coo : Create a Series with sparse values from a scipy.sparse.coo_matrix. Examples -------- >>> ser = pd.Series([0, 0, 2, 2, 2], dtype="Sparse[int]") >>> ser.sparse.density 0.6 >>> ser.sparse.sp_values array([2, 2, 2]) """ def _validate(self, data) -> None: if not isinstance(data.dtype, SparseDtype): raise AttributeError(self._validation_msg) def _delegate_property_get(self, name: str, *args, **kwargs): return getattr(self._parent.array, name) def _delegate_method(self, name: str, *args, **kwargs): if name == "from_coo": return self.from_coo(*args, **kwargs) elif name == "to_coo": return self.to_coo(*args, **kwargs) else: raise ValueError @classmethod def from_coo(cls, A, dense_index: bool = False) -> Series: """ Create a Series with sparse values from a scipy.sparse.coo_matrix. This method takes a ``scipy.sparse.coo_matrix`` (coordinate format) as input and returns a pandas ``Series`` where the non-zero elements are represented as sparse values. The index of the Series can either include only the coordinates of non-zero elements (default behavior) or the full sorted set of coordinates from the matrix if ``dense_index`` is set to `True`. Parameters ---------- A : scipy.sparse.coo_matrix The sparse matrix in coordinate format from which the sparse Series will be created. dense_index : bool, default False If False (default), the index consists of only the coords of the non-null entries of the original coo_matrix. If True, the index consists of the full sorted (row, col) coordinates of the coo_matrix. Returns ------- s : Series A Series with sparse values. See Also -------- DataFrame.sparse.from_spmatrix : Create a new DataFrame from a scipy sparse matrix. scipy.sparse.coo_matrix : A sparse matrix in COOrdinate format. Examples -------- >>> from scipy import sparse >>> A = sparse.coo_matrix( ... ([3.0, 1.0, 2.0], ([1, 0, 0], [0, 2, 3])), shape=(3, 4) ... ) >>> A >>> A.todense() matrix([[0., 0., 1., 2.], [3., 0., 0., 0.], [0., 0., 0., 0.]]) >>> ss = pd.Series.sparse.from_coo(A) >>> ss 0 2 1.0 3 2.0 1 0 3.0 dtype: Sparse[float64, nan] """ from pandas import Series from pandas.core.arrays.sparse.scipy_sparse import coo_to_sparse_series result = coo_to_sparse_series(A, dense_index=dense_index) result = Series(result.array, index=result.index, copy=False) return result def to_coo( self, row_levels=(0,), column_levels=(1,), sort_labels: bool = False ) -> tuple[coo_matrix, list, list]: """ Create a scipy.sparse.coo_matrix from a Series with MultiIndex. Use row_levels and column_levels to determine the row and column coordinates respectively. row_levels and column_levels are the names (labels) or numbers of the levels. {row_levels, column_levels} must be a partition of the MultiIndex level names (or numbers). Parameters ---------- row_levels : tuple/list MultiIndex levels to use for row coordinates, specified by name or index. column_levels : tuple/list MultiIndex levels to use for column coordinates, specified by name or index. sort_labels : bool, default False Sort the row and column labels before forming the sparse matrix. When `row_levels` and/or `column_levels` refer to a single level, set to `True` for a faster execution. Returns ------- y : scipy.sparse.coo_matrix The sparse matrix in coordinate format. rows : list (row labels) Labels corresponding to the row coordinates. columns : list (column labels) Labels corresponding to the column coordinates. See Also -------- Series.sparse.from_coo : Create a Series with sparse values from a scipy.sparse.coo_matrix. Examples -------- >>> s = pd.Series([3.0, np.nan, 1.0, 3.0, np.nan, np.nan]) >>> s.index = pd.MultiIndex.from_tuples( ... [ ... (1, 2, "a", 0), ... (1, 2, "a", 1), ... (1, 1, "b", 0), ... (1, 1, "b", 1), ... (2, 1, "b", 0), ... (2, 1, "b", 1), ... ], ... names=["A", "B", "C", "D"], ... ) >>> s A B C D 1 2 a 0 3.0 1 NaN 1 b 0 1.0 1 3.0 2 1 b 0 NaN 1 NaN dtype: float64 >>> ss = s.astype("Sparse") >>> ss A B C D 1 2 a 0 3.0 1 NaN 1 b 0 1.0 1 3.0 2 1 b 0 NaN 1 NaN dtype: Sparse[float64, nan] >>> A, rows, columns = ss.sparse.to_coo( ... row_levels=["A", "B"], column_levels=["C", "D"], sort_labels=True ... ) >>> A >>> A.todense() matrix([[0., 0., 1., 3.], [3., 0., 0., 0.], [0., 0., 0., 0.]]) >>> rows [(1, 1), (1, 2), (2, 1)] >>> columns [('a', 0), ('a', 1), ('b', 0), ('b', 1)] """ from pandas.core.arrays.sparse.scipy_sparse import sparse_series_to_coo A, rows, columns = sparse_series_to_coo( self._parent, row_levels, column_levels, sort_labels=sort_labels ) return A, rows, columns def to_dense(self) -> Series: """ Convert a Series from sparse values to dense. Returns ------- Series: A Series with the same values, stored as a dense array. Examples -------- >>> series = pd.Series(pd.arrays.SparseArray([0, 1, 0])) >>> series 0 0 1 1 2 0 dtype: Sparse[int64, 0] >>> series.sparse.to_dense() 0 0 1 1 2 0 dtype: int64 """ from pandas import Series return Series( self._parent.array.to_dense(), index=self._parent.index, name=self._parent.name, copy=False, ) class SparseFrameAccessor(BaseAccessor, PandasDelegate): """ DataFrame accessor for sparse data. It allows users to interact with a `DataFrame` that contains sparse data types (`SparseDtype`). It provides methods and attributes to efficiently work with sparse storage, reducing memory usage while maintaining compatibility with standard pandas operations. Parameters ---------- data : scipy.sparse.spmatrix Must be convertible to csc format. See Also -------- DataFrame.sparse.density : Ratio of non-sparse points to total (dense) data points. Examples -------- >>> df = pd.DataFrame({"a": [1, 2, 0, 0], "b": [3, 0, 0, 4]}, dtype="Sparse[int]") >>> df.sparse.density np.float64(0.5) """ def _validate(self, data) -> None: dtypes = data.dtypes if not all(isinstance(t, SparseDtype) for t in dtypes): raise AttributeError(self._validation_msg) @classmethod def from_spmatrix(cls, data, index=None, columns=None) -> DataFrame: """ Create a new DataFrame from a scipy sparse matrix. Parameters ---------- data : scipy.sparse.spmatrix Must be convertible to csc format. index, columns : Index, optional Row and column labels to use for the resulting DataFrame. Defaults to a RangeIndex. Returns ------- DataFrame Each column of the DataFrame is stored as a :class:`arrays.SparseArray`. See Also -------- DataFrame.sparse.to_coo : Return the contents of the frame as a sparse SciPy COO matrix. Examples -------- >>> import scipy.sparse >>> mat = scipy.sparse.eye(3, dtype=int) >>> pd.DataFrame.sparse.from_spmatrix(mat) 0 1 2 0 1 0 0 1 0 1 0 2 0 0 1 """ from pandas._libs.sparse import IntIndex from pandas import DataFrame data = data.tocsc() index, columns = cls._prep_index(data, index, columns) n_rows, n_columns = data.shape # We need to make sure indices are sorted, as we create # IntIndex with no input validation (i.e. check_integrity=False ). # Indices may already be sorted in scipy in which case this adds # a small overhead. data.sort_indices() indices = data.indices indptr = data.indptr array_data = data.data dtype = SparseDtype(array_data.dtype) arrays = [] for i in range(n_columns): sl = slice(indptr[i], indptr[i + 1]) idx = IntIndex(n_rows, indices[sl], check_integrity=False) arr = SparseArray._simple_new(array_data[sl], idx, dtype) arrays.append(arr) return DataFrame._from_arrays( arrays, columns=columns, index=index, verify_integrity=False ) def to_dense(self) -> DataFrame: """ Convert a DataFrame with sparse values to dense. Returns ------- DataFrame A DataFrame with the same values stored as dense arrays. See Also -------- DataFrame.sparse.density : Ratio of non-sparse points to total (dense) data points. Examples -------- >>> df = pd.DataFrame({"A": pd.arrays.SparseArray([0, 1, 0])}) >>> df.sparse.to_dense() A 0 0 1 1 2 0 """ data = {k: v.array.to_dense() for k, v in self._parent.items()} return self._parent._constructor( data, index=self._parent.index, columns=self._parent.columns ) def to_coo(self) -> spmatrix: """ Return the contents of the frame as a sparse SciPy COO matrix. Returns ------- scipy.sparse.spmatrix If the caller is heterogeneous and contains booleans or objects, the result will be of dtype=object. See Notes. See Also -------- DataFrame.sparse.to_dense : Convert a DataFrame with sparse values to dense. Notes ----- The dtype will be the lowest-common-denominator type (implicit upcasting); that is to say if the dtypes (even of numeric types) are mixed, the one that accommodates all will be chosen. e.g. If the dtypes are float16 and float32, dtype will be upcast to float32. By numpy.find_common_type convention, mixing int64 and and uint64 will result in a float64 dtype. Examples -------- >>> df = pd.DataFrame({"A": pd.arrays.SparseArray([0, 1, 0, 1])}) >>> df.sparse.to_coo() """ import_optional_dependency("scipy") from scipy.sparse import coo_matrix dtype = find_common_type(self._parent.dtypes.to_list()) if isinstance(dtype, SparseDtype): dtype = dtype.subtype cols, rows, data = [], [], [] for col, (_, ser) in enumerate(self._parent.items()): sp_arr = ser.array row = sp_arr.sp_index.indices cols.append(np.repeat(col, len(row))) rows.append(row) data.append(sp_arr.sp_values.astype(dtype, copy=False)) cols_arr = np.concatenate(cols) rows_arr = np.concatenate(rows) data_arr = np.concatenate(data) return coo_matrix((data_arr, (rows_arr, cols_arr)), shape=self._parent.shape) @property def density(self) -> float: """ Ratio of non-sparse points to total (dense) data points. See Also -------- DataFrame.sparse.from_spmatrix : Create a new DataFrame from a scipy sparse matrix. Examples -------- >>> df = pd.DataFrame({"A": pd.arrays.SparseArray([0, 1, 0, 1])}) >>> df.sparse.density np.float64(0.5) """ tmp = np.mean([column.array.density for _, column in self._parent.items()]) return tmp @staticmethod def _prep_index(data, index, columns): from pandas.core.indexes.api import ( default_index, ensure_index, ) N, K = data.shape if index is None: index = default_index(N) else: index = ensure_index(index) if columns is None: columns = default_index(K) else: columns = ensure_index(columns) if len(columns) != K: raise ValueError(f"Column length mismatch: {len(columns)} vs. {K}") if len(index) != N: raise ValueError(f"Index length mismatch: {len(index)} vs. {N}") return index, columns